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Lara, Enrique
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Lara, Enrique
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- PublicationAccès librerRNA Phylogeny of Arcellinida (Amoebozoa) Reveals that the Largest Arcellinid Genus, Difflugia Leclerc 1815, is not Monophyletic(2012)
; The systematics of lobose testate amoebae (Arcellinida), a diverse group of shelled free-living unicellular eukaryotes, is still mostly based on morphological criteria such as shell shape and composition. Few molecular phylogenetic studies have been performed on these organisms to date, and their phylogeny suffers from typical under-sampling artefacts, resulting in a still mostly unresolved tree. In order to clarify the phylogenetic relationships among arcellinid testate amoebae at the inter-generic and inter-specific level, and to evaluate the validity of the criteria used for taxonomy, we amplified and sequenced the SSU rRNA gene of nine taxa - Difflugia bacillariarum, D. hiraethogii, D. acuminata, D. lanceolata, D. achlora, Bullinularia gracilis, Netzelia oviformis, Physochila griseola and Cryptodifflugia oviformis. Our results, combined with existing data demonstrate the following: 1) Most arcellinids are divided into two major clades, 2) the genus Difflugia is not monophyletic, and the genera Netzelia and Arcella are closely related, and 3) Cryptodifflugia branches at the base of the Arcellinida clade. These results contradict the traditional taxonomy based on shell composition, and emphasize the importance of general shell shape in the taxonomy of arcellinid testate amoebae. - PublicationAccès libreMolecular phylogeny and taxonomy of Testate amoebae (protist) and host-symbiont evolutionary relationships within mixotrophic taxa(2012)
; Les recherches en phylogénie moléculaire ont considérablement avancé notre compréhension des relations entre eucaryotes. Les classifications récentes placent les protistes amoeboides dans plus de 30 lignées au sein des Amoebozoa, Rhizaria, Stramenopiles, Opisthokonta, et Excavata. Parmi celles-ci, certaines branches ont développé des thèques ou coquilles, souvent ornementées et caractéristiques qui ont été utilisées depuis plus de 150 ans comme caractère diagnostique pour décrire plus de 2000 espèces. Les thécamoebiens sont caractérisés par des pseudopodes lobés ou filamenteux et une thèque à une chambre pouvant être agglutinée, protéinique, calcaire ou siliceuse. L’acquisition de la thèque s’est faite plusieurs fois de manière indépendante au cours de l’évolution. De plus, et malgré la longue tradition de recherche en taxonomie sur les thécamoebiens, les relations entre les différents taxons demeurent largement non-résolue, l’affiliation phylogénétique de certains genres restant inconnue.
Le but de cette thèse était de construire une phylogénie fiable du plus grand ordre d’amibes, les Arcellinida, en utilisant des séquences du gène SSU rRNA et des analyses par microscopie électronique (chapitres 2 et 5). Les résultats révèlent des contradictions drastiques avec la taxonomie traditionnelle. Le genre Difflugia, le plus grand genre des Arcellinida, n’est pas monophylétique et est divisé en deux clades bien distincts regroupant respectivement les espèces allongées/pyriformes et les espèces globulaires. Le genre Netzelia est phylogénétiquement proche des Difflugia globulaires malgré les différences de structures de leur thèque.
Par ailleurs, les Arcellinida démontrent un conservatisme morphologique marqué; les types morphologiques similaires correspondant possiblement à des taxons génétiquement très distants. Nous démontrons la possibilité d’une évolution morphologique rapide an sein de ce groupe. Difflugia tuberspinifera, une espèce endémique d’Asie possède deux morpho-types (avec et sans cornes) possédant des séquences similaire du gène SSU rRNA gene (99.8%) et des introns et insertions identiques, mais pouvant toutefois être discriminés sur la base de leur séquences. Ceci suggère une évolution morphologique récente, possiblement liée à des facteurs écologiques à déterminer.
Nous avons déterminé la position phylogénétique des deux genresincertae sedis bien connus de la famille des Amphitrematidae, Amphitrema et Archerella (chapitre 3), qui de manière surprenante sont apparentés Labyrinthulomycetes (Stramenopiles), formant ainsi un nouveau clade de thécamoebiens indépendants des autres (c.à .d. Amoebozoa & Rhizaria). Cette étude illustre également que la taxonomie et la phylogénie des protistes en général est d’une importance cruciale pour comprendre l’évolution de la diversité des eucaryotes.
Les thécamoebiens forment souvent des associations avec les organismes photosynthétiques dont l’identité demeure toutefois inconnue. Nous avons identifié les symbiontes de quatre thécamoebiens différents sur la base du gène chloroplastique rbcL (ribulose-1, 5-diphosphate carboxylase/oxygénase grande sub-unité) utilisé comme gène de barcoding. La majorité des symbiontes de thécamoebiens ont pu être raisonnablement associés à une seule espèce, malgré le fait que leurs hôtes étaient taxonomiquement très distants. Fait intéressant, les Chlorelles symbiontes des thécamoebiens étaient très proches de Chlorella variabilis ainsi que des symbiontes de Paramecium bursaria. A la lumière de ces résultats, nous proposons un scénario d’évolution de l’association entre hôtes hétérotrophes et leur symbiontes photosynthétiques.
De manière générale, ma thèse illustre qu’une phylogénie fiable des thécamobiens basée sur les approches morphologiques et moléculaires est non-seulement un prérequis essentiel pour comprendre leur évolution, mais contribuera aussi à résoudre des débats concernant leur diversité et leur biogéographie, et en augmentera en général leur utilisé comme groupe modèle d’organismes pour les recherches en écologie appliquée., Molecular phylogenetic studies have considerably advanced our understanding of the relationships among eukaryotes. In recent classification schemes, amoeboid protists appeared scattered in more than 30 lineages within Amoebozoa, Rhizaria, Stramenopiles, Opisthokonta, and Excavata. Amongst these, some branches tended to develop a test or shell, often ornamented and conspicuous, which has been used for more than 150 years as a diagnostic character to describe more than 2000 species. Testate amoebae are characterized by lobose or filose pseudopodia and one chamber shell that can be agglutinated, proteinaceous, calcareous or siliceous. The acquisition of the shell happened several times independently in the course of evolution. Furthermore, and in spite of the long taxonomic tradition in testate amoebae research, the relationships between the different taxa remained largely unresolved, some genera remaining still without known phylogenetic affiliation.
In this thesis, we aimed at constructing a reliable phylogeny of the largest testate amoebae order, the Arcellinida, using SSU rRNA gene sequences and scanning electron microscopy analyses (chapters 2 and 5). Our results revealed drastic contradictions with traditional taxonomy. Genus Difflugia, the largest Arcellinid genus appeared not monophyletic, and divided in two major and distantly related clades that grouped respectively the elongated/pyriform and the globular species. Genus Netzelia was phylogenetically very closely related to the globular Difflugia despite the inconsistencies in their shell structure.
In addition, Arcellinida tended to show an important morphological conservatism, and closely related morphologies can possibly hide important genetic distances. We also demonstrated that fast morphological evolution could also be possible in this group. Difflugia tuberspinifera, an Asian endemic species had two morphotypes (spiny and spineless) which shared highly similar SSU rRNA gene sequences (99.8%) and identical introns and insertions, but could be nevertheless discriminated on the base of their sequences. This result suggested a recent morphological evolution, presumably due to some differing ecological factors that still need to be clarified.
We determined also the phylogenetic position of two well known incertae sedis genera of family Amphitremida, Amphitrema and Archerella (chapter 3), which appeared surprisingly to be related to Labyrinthulomycetes (Stramenopiles), thus forming a new clade of testate amoebae independent from others (i.e Amoebozoa, Rhizaria). This study also illustrated that accurate taxonomy and phylogeny of protists in general is of crucial important for understanding the evolution and diversity of eukaryotes.
Testate amoebae have been also often found in association with some photosynthetic organisms whose identity remained unknown. We identified the symbionts of four different testate amoeba species using the chloroplastic gene rbcL (ribulose-1, 5-diphosphate carboxylase/oxygenase large subunit) as a barcoding gene. The majority of testate amoeba symbionts formed a consistent group with very few sequence diversity that could be reasonably associated to a single species, in spite of the fact that host species were taxonomically distantly related. Interestingly, testate amoebae Chlorella symbionts were very closely related to Chlorella variabilis and to Paramecium bursaria Chlorella symbionts. In the light of these results, we proposed a general evolutionary scenario for association between heterotrophic hosts and their photosynthetic symbionts.
Overall, my thesis illustrated that the reliable phylogeny of testate amoebae based on molecular and morphological approaches is not only essential prerequisite for understanding their evolution, but it also will contribute in resolving debates concerning their diversity and biogeography, and in general will increase their utility as a model group of organisms for applied ecological research. - PublicationAccès libreCOI Barcoding of Nebelid Testate Amoebae (Amoebozoa: Arcellinida): Extensive Cryptic Diversity and Redefinition of the Hyalospheniidae Schultze(2012)
; ; We used Cytochrome Oxidase Subunit 1 (COI) to assess the phylogenetic relationships and taxonomy of Nebela sensu stricto and similar taxa (Nebela group, Arcellinida) in order to clarify the taxonomic validity of morphological characters. The COI data not only successfully separated all studied morphospecies but also revealed the existence of several potential cryptic species. The taxonomic implications of the results are: (1) Genus Nebela is paraphyletic and will need to be split into at least two monophyletic assemblages when taxon sampling is further expanded. (2) Genus Quadrulella, one of the few arcellinid genera building its shell from self-secreted siliceous elements, and the mixotrophic Hyalosphenia papilio branch within the Nebela group in agreement with the general morphology of their shell and the presence of an organic rim around the aperture (synapomorphy for Hyalospheniidae). We thus synonymise Hyalospheniidae and Nebelidae. Hyalospheniidae takes precedence and now includes Hyalosphenia, Quadrulella (previously in the Lesquereusiidae) and all Nebelidae with the exception of Argynnia and Physochila. Leptochlamys is Arcellinida incertae sedis. We describe a new genus Padaungiella Lara et Todorov and a new species Nebela meisterfeldi n. sp. Heger et Mitchell and revise the taxonomic position (and rank) of several taxa. These results show that the traditional morphology-based taxonomy underestimates the diversity within the Nebela group, and that phylogenetic relationships are best inferred from shell shape rather than from the material used to build the shell. - PublicationMétadonnées seulementRibosomal RNA genes challenge the monophyly of the hyalospheniidae (Amoebozoa : Arcellinida)(2008)
; - PublicationAccès libreRibosomal RNA Genes Challenge the Monophyly of the Hyalospheniidae (Amoebozoa: Arcellinida)(2008)
; - PublicationAccès libreEight species in the Nebela collaris complex: Nebela gimlii (Arcellinida,Hyalospheniidae), a new species described from a Swiss raised bogWe describe here a new species of sphagnicolous testate amoeba found abundantly in the forested part of the Le Cachot peatland (Jura Mountains, Neuchâtel, Switzerland) based on microscopical observations (LM, SEM). The new species, called Nebela gimlii was placed in a phylogenetic tree based on mitochondrial cytochrome oxidase sequences (COI), and branched robustly within the N. collaris complex next to the morphologically similar N. guttata and N. tincta. It is however genetically clearly distinct from these two species, and differs morphologically from them by its smaller size and stouter shape of the shell. This new species completes the phylogeny of the Nebela collaris species complex, with now eight species described, mostly from peatlands and acidic forest litter, and further demonstrates the existence of an unknown diversity within testate amoebae. Improving the taxonomy of testate amoebae in peatlands and clarifying the ecology of newly discovered species should make these organisms even more valuable as bioindicator and for palaeoecological reconstruction.